Impedance matched transmitting arrangement

ABSTRACT

A transmitting arrangement includes a matching circuit, a reference circuit and a comparator. The output of the matching circuit can be coupled to an antenna and comprises an adjustable impedance. The reference circuit is connected to an input of the matching circuit and comprises a reference impedance. Inputs of the comparator are coupled to the matching circuit and the reference circuit and its output is coupled to the adjustable impedance via a control input of the matching circuit.

REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. patentapplication Ser. No. 11/540,050, which was filed on Sep. 29, 2006.Application Ser. No. 11/540,050 claims the benefit of the priority dateof German application DE 10 2005 047 155.2, filed on Sep. 30, 2005. Theentire content of application Ser. No. 11/540,050 German application DE10 2005 047 155.2 are hereby incorporated herein by reference.

FIELD OF THE INVENTION

Transmitting arrangements, the use of a transmitting arrangement and amethod for impedance matching are disclosed.

BACKGROUND OF THE INVENTION

Transmitting arrangements, particularly in devices of mobile radiocommunication, usually have a power transistor which is followed by anantenna. The characteristics of a real antenna which change in operationcan cause a mismatch of the power transistor to an impedance value ofthe antenna. The cause of such changes is mainly the changes in theenvironmental conditions of the antenna caused by the user of a deviceof the mobile radio communication. The device can be located, forexample, in a hand, on a metallic base or in a vehicle.

SUMMARY OF THE INVENTION

The following presents a simplified summary in order to provide a basicunderstanding of one or more aspects of the invention. This summary isnot an extensive overview of the invention, and is neither intended toidentify key or critical elements of the invention, nor to delineate thescope thereof. Rather, the primary purpose of the summary is to presentone or more concepts of the invention in a simplified form as a preludeto the more detailed description that is presented later.

A transmitting arrangement is disclosed that comprises a matchingcircuit, a reference circuit and a comparator. The matching circuit hasan adjustable impedance, and is configured to have its output coupled toan antenna. The reference circuit has a reference impedance and aninput, and is configured for its input to be coupled to an input of thematching circuit. The comparator has a first input, a second input andan output, and is configured to be coupled to the matching circuit viaits first input, to the reference circuit via its second input and to acontrol input of the adjustable impedance of the matching circuit viaits output.

To the accomplishment of the foregoing and related ends, the followingdescription and annexed drawings set forth in detail certainillustrative aspects and implementations of the invention. These areindicative of but a few of the various ways in which one or more aspectsof the present invention may be employed. Other aspects, advantages andnovel features of the invention will become apparent from the followingdetailed description of the invention when considered in conjunctionwith the annexed drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Throughout the discussion herein reference is made to the followingdrawings.

FIGS. 1A to 1C are schematic diagrams illustrating exemplarytransmitting arrangements according to the discussion herein.

FIGS. 2A to 2F are schematic diagrams illustrating an exemplaryadjustable impedance and a reference impedance as can be used, forexample, in transmitting arrangements according to FIGS. 1A to 1C.

FIGS. 3A to 3C are schematic diagrams illustrating exemplary adjustablecapacitances as can be used, for example, in the adjustable impedancesaccording to FIGS. 2A, 2C and 2E.

FIG. 4 is a timing diagram illustrating an exemplary temporal sequenceof an operation of a transmitting arrangement according to thediscussion herein.

FIGS. 5A to 5D are graphs illustrating results of a simulation of atransmitting arrangement according to the discussion herein.

FIGS. 6A and 6B are Smith diagrams illustrating an unmatched and amatched transmitting arrangement.

DETAILED DESCRIPTION OF THE INVENTION

One or more examples will now be described with reference to the drawingfigures, wherein like reference numerals are used to refer to likeelements throughout. It should be understood that the drawing figuresand following descriptions are merely illustrative and that they shouldnot be taken in a limiting sense. In the following description, forpurposes of explanation, numerous specific details are set forth inorder to provide a thorough understanding. It will be appreciated thatvariations of the illustrated systems and methods apart from thoseillustrated and described herein may exist and that such variations aredeemed as falling within the scope of the appended claims

FIG. 1A illustrates an example of a transmitting arrangement. Thetransmitting arrangement comprises a matching circuit 20′ and areference circuit 60′. An antenna 5 is coupled to an output 28 of thematching circuit 20′. The matching circuit 20′ has an input 21. Theinput 21 of the matching circuit 20′ is connected to the output 28 ofthe matching circuit 20′ via a series circuit formed with an inputcoupling impedance 31 and an adjustable impedance 26. The referencecircuit 60 has an input 61 which is connected to a reference potentialconnection 8 via an input coupling impedance 71 and a referenceimpedance 66 and a terminating impedance 75. The input 21 of thematching circuit is connected to the input 61 of the reference circuit.A tap 27 in the matching circuit 20′ between the input couplingimpedance 31 and the adjustable impedance 26 is connected to an output29 of the matching circuit 20′. Correspondingly, a tap 67 in thereference circuit 60′, which is located between the input couplingimpedance 71 and the reference impedance 66, is connected to an output69 of the reference circuit 60′. A comparator 1 is connected to theoutput 29 of the matching circuit 20′ at a first input 2 and to theoutput 69 of the reference circuit 60′ at a second input 3. Thecomparator 1 is connected to an input 30 of the matching circuit 20′ atan output 4. The input 30 of the matching circuit 20′ is connected to acontrol connection of the adjustable impedance 26.

A transmitting signal SP is supplied both to the input 21 of thematching circuit 20′ and to the input 61 of the reference circuit 60′.The nominal signal RS, which can be picked up at the tap 67 of thereference circuit 60′, and the actual signal IS which can be picked upat the tap 27 of the matching circuit 20′, are supplied to thecomparator 1. The comparator 1 forms from these a control signal ST bywhich the adjustable impedance 26 is controlled. At the output 28 of thematching circuit 20′, the matched transmitting signal SE can be pickedup which is supplied to the antenna 5. The input coupling impedance 31of the matching circuit 20′ and the input coupling impedance 71 of thereference circuit 60′ are used for decoupling the two circuits 20′, 60′from one another.

The adjustable impedance 26 is adjusted by the comparator 1 in such amanner that a mismatch of the transmitting arrangement to the antenna 5is mitigated.

FIG. 1B illustrates an example of a further development of the circuitarrangement according to FIG. 1A. The matching circuit 20 comprises,instead of the input coupling impedance 31 in the matching circuit 20′of FIG. 1A, a transistor 22 which is connected between the input 21 ofthe matching circuit 20 and the adjustable impedance 26. The transistor22 is connected to the input 21 at a control connection 23. Thetransistor 22 is connected to a supply voltage connection 9 forsupplying a supply voltage VC at a first connection 24 via a firstconnecting impedance 32. The first connection 24 of the transistor 22 isconnected to the output 28 of the circuit arrangement 20 via theadjustable impedance 26. A second connection of the transistor 22 iscoupled to the reference potential connection 8. At the first connection24 of the transistor 22, the tap 27 is located which is connected to theoutput 29 of the matching circuit 20.

The reference circuit 60 comprises, instead of the input couplingimpedance 71 in the reference circuit 60′ according to FIG. 1A, areference transistor 62. The reference transistor 62 is connectedbetween the input 61 and the reference impedance 66. The referencetransistor 62 is connected to the input 61 at a control connection 63.The reference transistor 62 is connected to the supply voltageconnection 9 for supplying the supply voltage VC via a first connectingimpedance 72 at a first connection and to the reference potentialconnection 8 via the series circuit formed of the reference impedance 66and the terminating impedance 75. At the first connection 64 of thereference transistor 62, the tap 67 is located which is connected to theoutput 69 of the reference circuit 60. The reference transistor 62 isconnected to the reference potential connection 8 at a second connection65.

The matching circuit 20 and the reference circuit 60 now comprise thetransistor 22 and the reference transistor 62 which has the effect thata reaction of a mismatch of the antenna 5 via the connection of theinputs 21 and 61 of the matching circuit 20 and of the reference circuit60, respectively, on the reference circuit 60 can be kept low. Thereference circuit 60 is thus able to deliver a nominal signal RS whichis not dependent on a temporal change in the characteristic of theantenna 5 and is used for determining the control signal ST. Thematching circuit 20 can be used for matching a transmitting signal SP tothe antenna 5 by providing a matched transmitting signal SE to theantenna 5.

FIG. 1C illustrates an example of a further development of the circuitarrangement according to FIG. 1B. The matching circuit 20″ comprises thetransistor 22 and a first, a second and a third parallel transistor 40,41, 42. The four transistors 22, 40, 41, 42 are in each case connectedto one another at a control connection and are connected to the input 21of the matching circuit 20″. The four transistors 22, 40, 41, 42 aresimilarly connected to one another at a first connection and coupled tothe supply voltage connection 9 for supplying the supply voltage VC viaa first connecting impedance 32′. The four transistors 22, 40, 41, 42are connected to one another and to the reference potential connection 8at a second connection. The four transistors 22, 40, 41, 42 are in eachcase connected to the tap 27 of the matching circuit at the firstconnection. The tap 27 is coupled to the output 28 of the matchingcircuit 20″ via the adjustable impedance 26. The tap 27 of the matchingcircuit 20″ is connected to an input 48 of the adjustable impedance 26,an output 49 of the adjustable impedance 26 is connected to the output28 of the matching circuit 20″. The adjustable impedance 26 comprises afirst and a second inductance 90, 91 and a first and a secondcapacitance 95, 96. The input 48 of the adjustable impedance 26 isconnected to the output 49 of the adjustable impedance 26 via a seriescircuit comprising the first inductance 90 and a second inductance 91. Atap between the first inductance 90 and a second inductance 91 isconnected to the reference potential connection 8 via the firstcapacitance 95. The output 49 of the adjustable impedance 26 isconnected to the reference potential connection 8 via the secondcapacitance 96.

The reference circuit 60″ comprises the reference transistor 62 which isconnected to the input 61 of the reference circuit 60″ at the controlconnection 63 and to the reference potential connection 8 at the secondconnection 65. At the first connection 64, the reference transistor 62is connected to the supply voltage connection 9 via the firstterminating impedance 72′. The first connection 64 of the referencetransistor 62 forms the tap 67 of the reference circuit 20″. The tap 67of the reference circuit 20″ is connected to the reference potentialconnection 8 via a series circuit comprising the reference impedance 66and the terminating impedance 75. The reference impedance 66 comprises afirst and a second reference inductance 93, 94 and a first and a secondreference capacitor 97, 98. The tap 67 is connected to an output of thereference impedance 66 via a series circuit comprising the first and thesecond reference inductance 93, 94. A node between the first referenceinductance 93 and the second reference inductance 94 is connected to thereference potential connection 8 via a first reference capacitor 97. Theoutput of the reference impedance 66 is connected to the referencepotential connection 8 via the second reference capacitor 98.

The comparator 1 is connected to the output 29 of the matching circuit20″ via a first amplitude detection means 11 and a coupling capacitor 15at the first input 2. The comparator 1 is connected to the output 69 ofthe reference circuit 60″ at the second connection 3 via a secondamplitude detection means 12 and via a further coupling capacitor 16.The comparator 1 is coupled to an input 30 of the matching circuit 20″via an amplifier 17 at an output 4. The input 30 of the matching circuit20″ is connected to a control input of the first capacitance and to acontrol input of the second capacitance 95, 96. The first and the secondmeans for amplitude determination 11, 12 in each case comprise a diode13, 14.

The four transistors 22, 40, 41, 42 and the reference transistor 62 areconstructed as npn bipolar transistors.

The transmitting signal SP comprises both a direct voltage and analternating voltage component. The transmitting signal SP is supplied tothe transistor 22 and the first, second, third parallel transistor 40,41, 42 and the reference transistor 62. The reference transistor 62, incombination with the reference impedance 66 and the terminatingimpedance 75, generates a nominal signal RS which can be picked up atthe output 69 of the reference circuit 60″. Similarly, the transistor 22and the first, second, third parallel transistor 40, 41, 42, incombination with the adjustable impedance 26 and the antenna 5, generatean actual signal IS which can be picked up at the tap 27 of the matchingcircuit 20″ and is forwarded to the comparator 1 via the output 29 ofthe matching circuit. The actual signal IS and the nominal signal RS aresupplied to a first and a second amplitude detector 11, 12 in each casevia coupling capacitors 15, 16. The amplitudes are supplied to thecomparator 1 at the first and the second input 2, 3. A signal at theoutput 4 of the comparator 1 is amplified by the amplifier 17 andsupplied as control signal ST to the control inputs of the firstcapacitance and of the second capacitance 95, 96 via the input 30 of thematching circuit 20″.

A mismatch of the transmitting arrangement to an antenna can thus bemitigated. The reference circuit 60″ needs little electrical powercompared with a power consumption of the matching circuit 20″. Since, inaddition, the adjustable impedance 26 and the reference impedance 66have the same circuit configuration, the transmitting path is replicatedby the reference path. The control signal ST is thus determined veryaccurately. The adjustable impedance 26 is thus accurately matched tothe antenna 5.

FIGS. 2A, 2C, 2E illustrate various examples of an adjustable impedance26 as can be used, for example, in the matching circuits 20, 20′, 20″,20″′ according to FIGS. 1A to 1C. FIGS. 2B, 2D and 2F illustrate variousexamples of a reference impedance 66 as can be used, for example, in thereference circuits 60, 60′, 60″, 60″′ according to FIGS. 1A to 1C.

FIG. 2A illustrates an adjustable impedance having a first inductance 90and a first capacitance 95. The first inductance 90 is connected betweenthe input 48 and the output 49 of the adjustable impedance. The firstcapacitance 95 is connected between the output 49 and the referencepotential connection 8.

The first capacitance 95 is constructed to be adjustable and has acontrol connection. The adjustable impedance therefore has a low-passcharacteristic, the cut-off value of which can be adjusted by thecapacitance of the variable first capacitance 95.

FIG. 2B illustrates the reference impedance which is constructed inaccordance with the adjustable impedance. The reference impedance has afirst reference inductance 93 and a first reference capacitor 97. Thefirst reference inductance 93 is connected between the input 78 and theoutput 79 of the reference impedance. The first reference capacitor 97connects the output 79 of the reference impedance to the referencepotential connection 8.

The reference impedance thus has few, if any, adjustable values. Itsconfiguration mimics that of the adjustable impedance according to FIG.2A.

FIG. 2C illustrates a development of the adjustable impedance accordingto FIG. 2A. In distinction from the adjustable impedance according toFIG. 2A, the first inductance 90 in the adjustable impedance 26according to FIG. 2C is controllable and has a control connection.

FIG. 2D illustrates a reference impedance like FIG. 2B and is used asreference impedance for the adjustable impedance according to FIG. 2C.

FIG. 2E illustrates a development of the adjustable impedance accordingto FIG. 2A. The adjustable impedance according to FIG. 2E comprises afirst and a second inductance 90, 91 and a first and a secondcapacitance 95, 96. A series circuit comprising the first and the secondinductance 90, 91 connects the input 48 and the output 49 of theadjustable impedance. A node between the first inductance 90 and thesecond inductance 91 is connected to the reference potential connection8 via the first capacitance 95 and the output 49 of the adjustableimpedance is connected to the reference potential connection 8 via thesecond capacitance 98.

The first and the second capacitance 95, 96 are designed to beadjustable and a control signal is applied to them.

The adjustable impedance according to FIG. 2E can thus be varied by twoadjusting possibilities.

FIG. 2F illustrates a reference impedance which is configuredcorrespondingly to the adjustable impedance according to FIG. 2E. Thereference impedance 66 comprises the first and the second referenceinductance 93, 94 and the first and the second reference capacitor 97,98. The input 78 is connected to the output 79 of the referenceimpedance 66 via a series circuit comprising the first and the secondreference inductance 93, 94. A node between a first and a secondreference inductance 93, 94 is connected to the reference potentialconnection 8 via the first reference capacitor 97. The output 79 of thereference impedance 66 is connected to the reference potentialconnection 8 via the second reference capacitor 98.

The reference impedance according to FIG. 2E has a configuration whichis comparable to the adjustable impedance according to FIG. 2E.

FIG. 3A illustrates an example of an adjustable capacitance which can,for example, be used as the first capacitance 95 or as a secondcapacitance 96 in the adjustable impedance 26 according to FIGS. 2A to2E or in other examples of the adjustable impedance.

The adjustable capacitance according to FIG. 3E has capacitors 100, 101,102 and a switch 120. A series circuit comprising the capacitor 100 andthe first capacitor 102 connect a connection of the adjustablecapacitance according to FIG. 3A to a further connection of theadjustable capacitance according to FIG. 3A. A series circuit isconnected in parallel with the first capacitor 102, the series circuitcomprising the second capacitor 101 and the switch 120. The switch 120,in one example, is constructed as N-channel metal oxide semiconductorfield effect transistor.

The switch 120 is supplied with a control signal STC. If the switch isin an open operating state, the capacitance value of the adjustablecapacitance can be calculated from the capacitance value of thecapacitor 100 and the capacitance value of the first capacitor 102approximately according to the following equation:

${{CE} = \frac{C\;{100 \cdot C}\; 102}{{C\; 100} + {C\; 102}}},$where CE is a capacitance value of the adjustable capacitance, C100 isthe capacitance value of the capacitor 100 and C102 is the capacitancevalue of the first capacitor 102. If the switch 120 is in a closedoperating state, the second capacitor 101 is switched to operate and thecapacitance of the adjustable capacitance can be calculatedapproximately according to the following equation.

${{CE} = \frac{C\;{100 \cdot \left( {{C\; 101} + {C\; 102}} \right)}}{{C\; 100} + {C\; 101} + {C\; 102}}},$where C101 is the capacitance value of the second capacitor 101.

A capacitance value can thus be increased and reduced by the switch 120and the control signal STC.

FIG. 3B illustrates an adjustable capacitance which comprises fivesubunits. The subunits are in each case connected in parallel betweenthe first connection and the second connection of the adjustablecapacitors. The first subunit comprises a third capacitor 103, a fourthcapacitor 104 and a switch 121. A series circuit comprising the thirdcapacitor 103 and the fourth capacitor 104 is connected between thefirst connection of the adjustable capacitance and the second connectionof the adjustable capacitance. The switch 121 is connected between anode between the third capacitor 103 and the fourth capacitor 104 andthe second connection of the adjustable capacitance. The second subunitcorrespondingly comprises a further third capacitor 105, a furtherfourth capacitor 106 and a switch 122 in corresponding interconnection.Correspondingly, the third and the fifth subunit is constructed with twocapacitors 107, 108; 109, 110; 111, 112 each and one switch 123, 124,125 each.

If the switch 121 is in a closed operating state, the capacitance valueof the third capacitor 103 contributes to the total capacitance value ofthe adjustable capacitance. If the switch 121 is in an open operatingstate, the series circuit comprising the third capacitor 103 and thefourth capacitor 104 contributes to the capacitance value of theadjustable capacitance. This applies to the second and the fifthsubunit. The switches 121, 122, 123, 124, 125 can be driven in each caseindividually by a control signal STC which comprises a number ofcomponents for separately driving the five switches 121 to 125.

By selectively adjusting the switches 121 to 125, various capacitancevalues of the adjustable capacitance can be achieved.

FIG. 3C illustrates an adjustable capacitance which can, for example, beused in FIGS. 2A, 2C and 2E. The adjustable capacitance according toFIG. 3C comprises a first and a second connection and a controlconnection. The adjustable capacitance according to FIG. 3C comprises acapacitor 113 and a capacitor 114 and resistors 180 to 186, varactordiodes 150 to 161 and a capacitor 115.

The adjustable capacitance according to FIG. 3C comprises a seriescircuit having the capacitor 113, the varactor diodes 150, 152, 154,156, 158, 160 and the capacitor 115. The varactor diode 150 is connectedin parallel with a varactor diode 151. Similarly, the varactor diodes153, 155, 157, 159, 161 are connected in parallel with the varactordiodes 152, 154, 156, 158, 160. A node between the capacitor 113 and thevaractor diode 150 is connected to the control connection of theadjustable capacitors via the resistor 180. Similarly, a node betweenthe varactor diodes 152 and 154 is connected to the control connectionvia the resistor 182. Furthermore, a node between the varactor diodes156 and 158 is connected to the control connection via the resistor 184.A node between the varactor diode 160 and the capacitor 150 is connectedto the control connection via the resistor 186. A node between thevaractor diode 150 and the varactor diode 152 is connected to the secondconnection of the adjustable capacitance via the resistor 181.Similarly, a node between the varactor diode 154 and the varactor diode156 is connected via the resistor 183, and a node between the varactordiode 158 and the varactor diode 160 is connected via the resistor 185,to the second connection of the adjustable capacitance. The firstconnection of the adjustable capacitance is connected to the secondconnection of the adjustable capacitance via the capacitor 114. Thevaractor diodes 150 to 161 are connected in such a manner that an anodeis in each case connected to the resistors 181, 183, 185 and a cathodeis in each case connected to the resistors 180, 182, 186.

The capacitance value of the varactor diodes can be adjusted via acontrol signal STV which is supplied to the varactor diodes 150 to 161via the resistors 180, 182, 184 and 186 so that a total capacitancevalue of the adjustable capacitance according to FIG. 3C can beadjusted.

FIG. 4 illustrates an exemplary variation with time of an operation of atransmitting arrangement. Slots in which transmission takes place areplotted against time t. Furthermore, a capacitance value C1 on the firstcapacitance 95 and a capacitance value C2 of the second capacitance 96is plotted against time t.

During slots 1 to 5, a matched transmitting signal SE to be transmittedis present at the antenna 5. During slots 1 to 5, the actual signal ISis compared by the comparator 1 with the nominal signal RS and thecontrol signal ST is formed. According to FIG. 4, the comparison isperformed at times t1, t3, t5, t7 and t9.

The method provides that the matching circuit 26 is set to a startingstate at the beginning of transmitting operation. In the methodillustrated in FIG. 4, the adjustable impedance is adjusted more andmore accurately in further steps.

At the beginning, that is to say during slot S1, the first capacitance95 and the second capacitance 96 in each case have a startingcapacitance value C1S and C2S, respectively. At the beginning of slot 2,the first capacitance 95 is adjusted. This is the case at time t2. Attime t4, the beginning of slot 3, at time t6, the beginning of slot 4,and at time t8, the beginning of slot 5, the capacitance value C2 of thesecond capacitance 96 is adjusted.

In the case of a first capacitance 95 which has two capacitance values,one slot is adequate for adjusting the first capacitance 95. In the caseof a second capacitance 96 which comprises a five-bit-adjustmentcapability, up to 25 slots, that is to say 32 slots, are necessary forthe adjustment. If the transistor 22 of the matching circuit is switchedfrom one power stage into another power stage, the adjustablecapacitances 95, 96, and thus the adjustable impedance 26, are set to astarting value. Following this, the adjustment process illustrated inFIG. 4 starts.

FIGS. 5A to 5D illustrate results of a simulation with a transmittingarrangement as described herein. In this simulation, results weresimulated with various mismatches, designated by P1 to P8, and with a50-ohm match. To simulate the mismatch, a network of two inductances andtwo capacitors was connected between the matching circuit 20 and theantenna 5 which was taken into consideration as a 50-ohm wave impedance.

FIG. 5A illustrates the upward power Pout of the transistor 22 of thematching circuit plotted against a state with matched operation at 50ohms and the eight points P1 to P8 with mismatch. The various curves inFIG. 5A illustrate various adjustments or embodiments of the matchingcircuit such as nominal values E1 and optimum values E2 which wereachieved by very fine adjustment of the capacitance values C1, C2. Thevalues E3 are obtained with a first capacitance 95 which is adjustableto two capacitance values C1, and a finely adjustable second capacitance96. The values E4 were achieved with the two capacitance values C1 of afirst capacitance 95, which is adjustable by switches, and a secondcapacitance 96 with three capacitors and a switch in CMOS technology.The values E5 are obtained with the capacitance values C1, C2 of a firstand second capacitance 95, 96, which is adjustable by switches, whereina five-bit adjustment capability was provided for the first capacitance95. The values E6 were achieved with the capacitance values C1, C2 of afirst capacitance 95, which is adjustable by switches, and a secondcapacitance 96 which is adjustable by varactor diodes.

The nominal values E1 deviate from the optimum values E2 and aredistinctly lower.

FIG. 5B illustrates the improvement of the output power of thetransistor for the various adjustments of the matching circuit whichlead to the values B, C, D, E, F.

FIG. 5C illustrates the efficiency PAE of the transistor for the variousadaptation methods.

FIG. 5D illustrates a voltage standing wave ratio before and afteroptimization. The nominal values E1, the optimum values E2 and thevalues E4 which can be achieved with a first capacitance 95 which isadjustable by switches, are plotted. FIG. 5D illustrates that theoptimum values E2 and the values E4 which can be achieved with a firstcapacitance 95 are distinctly better than the nominal values E1. Thevalues E4 are of the order of magnitude of the optimum values E2.

FIG. 6A illustrates a Smith diagram of an unmatched transmittingarrangement. Compared with the preceding transistors, a real antenna 5has a complex impedance which can be taken into consideration as a50-ohm impedance with some parasitic components.

FIG. 6A illustrates a Smith diagram with a transistor and a matchingcircuit and an unmatched antenna. At the transistor output, a voltagestanding wave ratio of 3:1 occurs. The low impedance at point 1 in theSmith diagram, which occurs at the collectors of the transistors, ismatched to 50 ohms, point 5 in the Smith diagram, by nominal transistorload elements. Due to the parasitic components in the antenna circuit,point 5 is changed into a point 7 at which the voltage standing waveratio is 3:1.

FIG. 6B illustrates a Smith diagram of a matched transmittingarrangement. Adjusting two capacitances in the matching circuit has theeffect that point 7 in FIG. 6B is much closer to the 50-ohms point inthe centre of the Smith diagram than in the Smith diagram according toFIG. 6A.

Accordingly, according to the disclosure herein, in one example, atransmitting arrangement comprises a matching circuit, a referencecircuit and a comparator. The matching circuit has an adjustableimpedance, and is configured to have its output coupled to an antenna.The reference circuit has a reference impedance and an input, and isconfigured for its input to be coupled to an input of the matchingcircuit. The comparator has a first input, a second input and an output,and is configured to be coupled to the matching circuit via its firstinput, to the reference circuit via its second input and to a controlinput of the adjustable impedance of the matching circuit via itsoutput.

In another example, a transmitting arrangement comprises a matchingcircuit with an input; a transistor which is coupled to the input of thematching circuit at a control input; an adjustable impedance which isconnected to the transistor; and an output which is connected to a firstconnection of the transistor via the adjustable impedance and which canbe coupled to an antenna. The transmitting arrangement further comprisesa reference circuit with an input which is connected to the input of thematching circuit; a reference transistor which is coupled to the inputof the reference circuit at a control input; and a reference impedancewhich is connected to the reference transistor. The transmittingarrangement further comprises a comparator with a first input which iscoupled to a tap of the matching circuit; a second input which iscoupled to a tap of the reference circuit; and an output which iscoupled to a control input of the adjustable impedance via a controlinput of the matching circuit.

In another example, a method for impedance matching comprises supplyinga transmitting signal to a reference circuit and a matching circuit;picking up a nominal signal in the reference circuit; picking up anactual signal in the matching circuit; comparing the nominal signal andthe actual signal; and adjusting an adjustable impedance in the matchingcircuit, in dependence on which an impedance-matched transmitting signalis delivered at the output end in dependence on a comparison result.

In another example, a transmitting arrangement provides a matchingcircuit, a reference circuit and a comparator. The matching circuitcomprises an adjustable impedance and can be coupled to an output withan antenna. The reference circuit is coupled to an input of the matchingcircuit at an input. The reference circuit has a reference impedance.The comparator is coupled to the matching circuit at a first input andto the reference circuit at a second input. The comparator is coupled tothe adjustable impedance via a control input of the matching circuit atan output. A transmitting signal can be applied to the matching circuitand to the reference circuit at the input end. A nominal signal can bepicked up in the reference circuit and an actual signal can be picked upin the matching circuit. The comparator is used for comparing thenominal signal with the actual signal. The result of the comparison canbe supplied to the adjustable impedance of the matching circuit in theform of a control signal. At the output of the matching circuit, amatched transmitting signal can be picked up.

The adjustable impedance can be adjusted in such a manner that thetransmitting arrangement can be matched to a changing real antennaimpedance. A mismatch of the antenna is mitigated even when theenvironmental conditions of the antenna change. A voltage standing waveratio can be reduced by the transmitting arrangement.

The comparator can have a differential amplifier connected to the firstinput of the comparator at one input and to the second input of thecomparator at a further input. The differential amplifier is connectedto the output of the comparator at an output.

The comparator can be constructed as comparing circuit.

The transmitting arrangement can comprise a first and a second amplitudedetector. The first amplitude detector is connected between the matchingcircuit and the comparator. It is designed for determining an amplitudeof the actual signal of the matching circuit. The second amplitudedetector is connected between the reference circuit and the second inputof the comparator and is designed for determining an amplitude of thenominal signal.

The first and the second amplitude detector can each have a diode. Thefirst and the second amplitude detector can be constructed as resettablepeak value rectifiers.

An amplifier can be connected between the output of the comparator andthe control input of the matching circuit. The amplifier can beimplemented as a linear amplifier, also called proportional amplifier,abbreviated P amplifier. The amplifier can also be constructed as aproportional-integral amplifier, abbreviated PI amplifier. The amplifiercan also be constructed as a proportional-integral-differentialamplifier, abbreviated PID amplifier.

In another example, the transmitting arrangement comprises a controlloop. The actual signal of the control loop can be picked up in thematching circuit and is supplied to the first input of the comparator.The nominal signal of the control loop can be picked up in the referencecircuit and is supplied to the second input of the comparator. Thecomparator is designed for determining a control deviation by comparingthe actual and the nominal signal. The control deviation is amplified bythe amplifier and produces a change in the adjustment of the adjustableimpedance of the matching circuit so that the control loop is closed.The control loop can be operated during the transmitting operation anddue to the coupling of the matching circuit and the reference circuit atthe input end, the transmitting signal can be applied to both.

The adjustable impedance can be designed for producing an impedancematch to the impedance value of the antenna which can be coupled to thetransmitting arrangement.

The reference impedance and the adjustable impedance can have the samecircuit configuration. An impedance spectrum of the reference impedanceand an impedance spectrum of the adjustable impedance is approximatelyequal apart from a constant multiplication factor. This is the case inthe frequency range which is provided for the transmitting arrangement.The multiplication factor is a real number.

The adjustable impedance can have at least one adjustable capacitance.

The adjustable capacitance can comprise a parallel circuit of a firstcapacitor and a series circuit which comprises a second capacitor and aswitch. If the switch is in a closed operating state, the adjustablecapacitance has a high capacitance value. If the switch is in an openoperating state, the adjustable capacitance has a low capacitance value,namely the capacitance value of the first capacitor.

In another example, the adjustable capacitance has a series circuitwhich comprises a third capacitor and a parallel circuit which has afourth capacitor and a switch. If the switch is in a closed operatingstate, the fourth capacitor is short circuited and the adjustablecapacitance thus has a high capacitance value, namely the capacitancevalue of the third capacitor. If the switch is in an open operatingstate, the capacitance value of the adjustable capacitance is determinedby the capacitance values of the third capacitor and of the fourthcapacitor and is smaller than the capacitance value of the thirdcapacitor.

The adjustable capacitance can be constructed as an electricallyadjustable capacitance in the form of a micromechanical element. Theadjustable capacitance can also comprise a varactor diode.

The adjustable impedance can comprise an inductance. The inductance canbe constructed as thin-film inductance or as an inductance implementedby microsystem technology.

The inductance can also be constructed to be adjustable. The inductancevalue can be adjusted by adding or removing turns of a coil of thethin-film inductance or of the inductance implemented by microsystemtechnology.

The reference impedance can comprise at least one reference capacitorand/or inductance.

In another example, the adjustable impedance comprises an inductancewhich is connected between an input and an output of the adjustableimpedance, and a capacitance which is connected between the output ofthe adjustable impedance and a reference potential connection.Accordingly the reference impedance comprises an inductance which isconnected between an input and an output of the reference impedance, anda reference capacitor which is connected between the output of thereference impedance and the reference potential connection.

In another example, the matching circuit comprises at least onetransistor and the reference circuit comprises at least one referencetransistor. The at least one transistor of the matching circuit iscoupled to the input of the matching circuit at a control input, to theoutput of the matching circuit and to a supply voltage connection viathe adjustable impedance at a first connection and to the referencepotential connection at a second connection. The reference transistor iscoupled to the input of the reference circuit at a control input, to aterminating impedance and to the supply voltage connection via thereference impedance at a first connection and to the reference potentialconnection at a second connection. The output of the adjustableimpedance is connected with respect to the transistor. The adjustableimpedance is used for mitigating a reaction of the mismatch of theantenna to the transistor. The transistor and the circuitry of thetransistor can thus be designed for the case of an ideal match of theantenna since temporal changes in the characteristic of the antennareact only slightly on the transistor due to the interconnectedadjustable impedance.

The adjustable impedance can be connected between the first connectionof the at least one transistor and the supply voltage connection and thereference impedance is connected between the first connection of thereference transistor and the supply voltage connection.

The adjustable impedance can be connected between the second connectionof the at least one transistor and the reference potential connectionand the reference impedance is connected between the second connectionof the reference transistor and the reference potential connection.

The terminating impedance can be constructed as wave impedance and/orreal wave impedance.

The matching circuit can comprise a metal oxide semiconductor fieldeffect transistor, abbreviated MOSFET, and the reference circuitcomprises a reference metal oxide semiconductor field effect transistor,abbreviated reference MOSFET. The MOSFET of the matching circuitexhibits a channel width and a channel length. Similarly, the referenceMOSFET comprises a channel width and a channel length. The MOSFET of thematching circuit can have a higher ratio of channel width and channellength compared with the reference MOSFET in order to provide for ahigher current driver capability of the MOSFET in the matching circuitcompared with the reference MOSFET. A ratio of the channel width tochannel length of the MOSFET of the matching circuit divided by a ratioof channel width and channel length of the reference MOSFET isapproximately equal to a ratio of an impedance value of the referenceimpedance and an impedance value of the adjustable impedance. Thus, theactual signal and the nominal signal are at approximately the samevoltage level.

In another example, the matching circuit comprises the transistor andN−1 further transistors which are connected in parallel at the input andoutput end. Thus, a first number N of transistors are connected inparallel in the matching circuit. The adjustable impedance is connectedbetween the common output of the first number N of transistors and theoutput of the matching circuit. The reference circuit has a transistor.An impedance spectrum of the reference impedance and an impedancespectrum of the adjustable impedance is approximately equal apart fromthe constant multiplication factor, the first number N, wherein thereference impedance has higher values than the adjustable impedance.

The matching circuit and the reference circuit can comprise pnp and/ornpn bipolar transistors.

In another example, a transmitting arrangement is provided which has amatching circuit, a reference circuit and a comparator. The matchingcircuit comprises an input, a transistor which is connected to the inputof the matching circuit at a control input, an adjustable impedancewhich is connected to the transistor, and an output which is coupled toa first connection of the transistor and which can be coupled to anantenna. The reference circuit comprises an input which is coupled tothe input of the matching circuit, a reference transistor which isconnected to the input of the reference circuit at a control input, anda reference impedance which is connected to the reference transistor.The comparator is coupled to a tap of the matching circuit at a firstinput via an output of the matching circuit, to a tap of the referencecircuit at a second input via an output of the reference circuit and hasan output which is coupled to a control input of the adjustableimpedance via a control input of the matching circuit.

In another example, a transmitting arrangement is provided whichcomprises a means for adjusting a transmitting signal on a transmittingpath and a reference means on a reference path. The means for adjustinga transmitting signal is connected in parallel with the reference meansat the input end. The transmitting arrangement also comprises a meansfor comparing which is designed for comparing an actual signal, whichcan be picked up on the transmitting path, and a nominal signal whichcan be picked up on the reference path, and delivering a control signalto the means for adjusting a transmitting signal. The means foradjusting a transmitting signal is constructed to be adjustable. As aresult, the transmitting arrangement can be matched to an antenna whichcan be coupled to the transmitting path.

The matching circuit, the reference circuit and the comparator can beproduced as integrated circuit from a semiconductor body. Thesemiconductor body and the integrated circuit can include the first andsecond amplitude detection means and the amplifier. The antenna can beconnected to the semiconductor body.

The transmitting arrangement can be used in a stationary transmittingarrangement or in a device of mobile radio communications.

In another example, a method for impedance matching comprises: pickingup a nominal signal in a reference circuit, picking up an actual signalin a matching circuit. The nominal signal and the actual signal arecompared with one another. An adjustable impedance in the matchingcircuit is adjusted in dependence on a result of the comparison. Thematching circuit outputs a matched transmitting signal at its outputend.

Thus, impedance matching to an impedance of an antenna can be performed.

The transmitting arrangement can perform impedance matching to atemporally changing impedance of an antenna.

A mismatch of the antenna may not lead to a reaction on the transistorpreceding the antenna.

The matching can be done very accurately by the control loop since anominal value is provided as reference value by the reference circuit.The determination of the nominal value takes into consideration theinstantaneous values of the signals of the transmitting arrangement tobe transmitted.

The circuit operates flexibly for different transmitting frequencies anddifferent power stages of the transistors in the matching and referencecircuit, respectively.

Although the invention has been illustrated and described with respectto certain aspects and/or embodiments, it is obvious that equivalentalterations and modifications will occur to others skilled in the artupon the reading and understanding of this specification and the annexeddrawings. In particular regard to the various functions performed by theabove described components (e.g., assemblies, devices, circuits, etc.),the terms (including a reference to a “means”) used to describe suchcomponents are intended to correspond, unless otherwise indicated, toany component which performs the specified function of the describedcomponent (i.e., that is functionally equivalent), even though notstructurally equivalent to the disclosed structure which performs thefunction in the herein illustrated exemplary embodiments of theinvention. In addition, while a particular feature of the invention mayhave been disclosed with respect to only one of several aspects of theinvention, such feature may be combined with one or more other featuresof the other aspects as may be desired and advantageous for any given orparticular application. Furthermore, to the extent that the term“includes” is used in either the detailed description or the claims,such term is intended to be inclusive in a manner similar to the term“comprising.” Also, “exemplary” is merely intended to mean an example,rather than “the best”.

1. A transmitting arrangement comprising a matching circuit comprisingan adjustable impedance; a reference circuit comprising a referenceimpedance and an input, and configured for the input to be coupled to aninput of the matching circuit, and a comparator comprising a firstinput, a second input and an output, and configured to be coupled to thematching circuit via the first input, to the reference circuit via thesecond input and to the adjustable impedance of the matching circuit viathe output.
 2. The transmitting arrangement of claim 1, the comparatorcomprising a differential amplifier, the inputs of which are coupled tothe first input of the comparator and the second input of the comparatorand the output of the differential amplifier is coupled to the output ofthe comparator.
 3. The transmitting arrangement of claim 1, thetransmitting arrangement comprising a first amplitude detectoroperatively coupled to the first input of the comparator, and a secondamplitude detector operatively coupled to the second input of thecomparator.
 4. The transmitting arrangement of claim 3, the firstamplitude detector comprising a first diode and the second amplitudedetector comprising a second diode.
 5. The transmitting arrangement ofclaim 1, the transmitting arrangement comprising an amplifier coupledbetween the output of the comparator and a control input of the matchingcircuit.
 6. The transmitting arrangement of claim 1, the adjustableimpedance configured to be adjusted for matching the transmittingarrangement to an impedance value of an antenna, the antenna coupled tothe matching circuit.
 7. The transmitting arrangement of claim 1, aratio of an amount of the reference impedance to an amount of theadjustable impedance being approximately constant for all frequencieswithin a predetermined frequency range.
 8. The transmitting arrangementof claim 1, the adjustable impedance comprising an adjustablecapacitance.
 9. The transmitting arrangement of claim 8, the adjustablecapacitance comprising a first capacitor, a second capacitor in parallelwith the first capacitor and a switch in series with the secondcapacitor.
 10. The transmitting arrangement of claim 8, the adjustablecapacitance comprising a series circuit of at least one third capacitorand at least one parallel circuit of a fourth capacitor and a switch.11. The transmitting arrangement of claim 8, the adjustable capacitancecomprising at least one varactor diode.
 12. The transmitting arrangementof claim 1, the adjustable impedance comprising at least one inductance.13. The transmitting arrangement of claim 12, the at least oneinductance of the adjustable impedance constructed to be adjustable. 14.The transmitting arrangement of claim 1, the reference impedancecomprising at least one reference capacitor.
 15. The transmittingarrangement of claim 1, the reference impedance comprising at least oneinductance.
 16. A method for impedance matching, comprising: supplying atransmitting signal to a reference circuit and a matching circuit,generating a nominal signal, generating an actual signal, comparing thenominal signal and the actual signal, and adjusting an adjustableimpedance based on the comparison of the nominal signal and the actualsignal.
 17. The method of claim 16, comprising: wherein the comparingact compares an amplitude of the actual signal with an amplitude of thenominal signal.